KR910000683B1 - Damper thermostat for refrigerator - Google Patents

Abstract

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Description

Damper Thermostat for Refrigerator

1 is a side cross-sectional view of a conventional refrigerator.

2 is a front view of a conventional refrigerator.

3 is an enlarged cross-sectional view of the main portion of FIG. 1 showing a conventional damper thermostat.

4 is a side cross-sectional view of a damper thermostat having the present invention.

5 is a cross-sectional view of an essential part of a refrigerator having a damper thermostat of the present invention.

6 to 9 are views for explaining the damper thermostat having the present invention.

* Explanation of symbols for main parts of the drawings

1: refrigerator body 2: inner box

3: outer box 5: freezer

6: cold storage room 7: partition wall

10: cooler 13: thermostat body

13a: thermal cylinder 13b: bellows

13c: operation plate 13d: damper

13e: spring 14: duct

14a: hole between the duct 15: insulation

The present invention relates to a damper thermostat for use in a refrigerator.

Conventionally, the refrigerator provided with the damper thermostat of this material is demonstrated according to FIG. 1 thru | or FIG. 3, (1) is a refrigerator main body, (2) the synthetic resin board was formed by vacuum molding etc. as an inner box. (3) was formed by bending a metal plate with an outer box. The inner space of the outer box is filled with a foamable heat insulating material 4 to form a heat insulating box body. 5 is a freezer compartment for storing frozen foods, and 6 is a refrigerator compartment for general food and vegetables. It is a part which cools and preserves etc. The freezer compartment 5 and the refrigerating compartment 6 are partitioned off by partition walls 7. 8 is a freezer compartment door that closes the front opening 5a of the freezer compartment 5. The front opening part 6a of the refrigerating compartment 6 is closed by the refrigerating compartment door. 10 is provided in the rear part of the freezer compartment 5 as a cooler. This cooler 10 forms part of a series of refrigeration cycles and is a cold air source for the freezer compartment 5 and the refrigerating compartment 6. 11 is located at the top of the cooler 10 by fins. The cold air cooled in (10) is forcibly circulated in the freezing chamber 5 and the refrigerating chamber 6. (11a) is a drive motor for rotating the fan 11. (12) The refrigerating chamber 6 A cold air outlet 12b is located at the center of the rear surface of the refrigerating compartment as a cold air supply passage of the cooling chamber. 12a is a cold air inlet provided in the freezer compartment 5. A main body of the damper thermostat describes the temperature in the refrigerating compartment as follows. The amount of cold air supplied to the refrigerating chamber 6 is adjusted by opening and closing the damper by sensing the heat sensing tube. Referring to the damper thermostat in FIG. 3, the damper thermostat 14 is in communication with the cold air outlet 12b as a duct, and has holes 14a between the ducts to discharge cold air toward the front of the refrigerating chamber as shown by the arrow. have. Ribs 14b are provided on the outer circumference of the holes 14a between the ducts. 13a is a heat-sensitive tube that senses the temperature in the refrigerating chamber and expands and contracts the thermal reactant, that is, the bellows 13b, to provide its expansion and contraction force. It cuts into the operation board 13c.

13c is a moving plate which balances the pressure of the bellows 13b and the force of the elastic body engaged with the operating plate 13C, that is, the string 13e, and rotates around the point 13 '. do.

13c is a damper and is rotatably connected to the operation plate at the coaxial portion 13d '. The damper is opened and closed by the operating plate 13c, but the damper 13d is attached to the inclined state (A dimension <B dimension) in the open state, and the lower end portion is in contact with the hole 14a between the ducts. The hole 14a between the ducts is opened and closed while rotating as the point.

Therefore, the opening and closing operation of the hole 14a between the ducts is determined by the rotational movement force of the operation plate 13c which moves the damper 13d, and keeps the temperature in the refrigerating chamber constant while optimally maintaining the amount of cold air supplied. Cold air supplied from the freezer compartment to the refrigerating compartment is changed upward by the inclination of the damper (l3d) and guided to the passage formed by the heat insulator 15 to be discharged into the refrigerating compartment and the meat case 16. It is a material having elasticity as a seal material, and is fixed between the heat insulating material 15 and the refrigerating chamber ceiling part 6b so that the cold air whose wind direction is changed upward does not cool the refrigerating compartment ceiling part 6b.

However, the refrigerating chamber having such a structure had the following drawbacks. That is, there is a drawback that the pressure loss becomes large due to the change in the air direction upward by the inclination of the damper and the cold air supplied and dropped from the freezer compartment to the refrigerating compartment. In addition, since the cold air is a wind direction discharged to the refrigerating chamber ceiling part, cryogenic cold air invades between the heat insulating material 15 and the refrigerating chamber ceiling part 6b and freezes, and is subsequently frosted by the temperature in the refrigerating chamber. Therefore, there is a drawback that the thickness of the heat insulating material 17 must be increased, or the thread reinforcement, such as attaching the real material 17, must be made to increase the number of parts.

It is an object of the present invention to provide a refrigerator which guides cold air that has been supplied and dropped from a freezer compartment to a refrigerator compartment downward to prevent frost on the refrigerator compartment ceiling.

In order to achieve the above object, the present invention uses the self-weight of the damper so that the damper is always inclined and at the same time the starting point of the damper opening is downward.

An embodiment of the present invention will be described with reference to FIGS. 4 and 5.

The same numerals as in the conventional example denote the same parts, and the structure of the refrigerator is the same as in the conventional example (FIGS. 1 to 3), and therefore, only the detailed views (FIGS. 4 and 5) of the damper thermostat will be described. 14 is a duct, which communicates with the cold air outlet 12b, and has holes 14a between the ducts to discharge cold air to the front of the refrigerating chamber, as indicated by arrows in FIG. A rib 14b is provided on the outer circumference of the hole 14a. [0027] The heat sink 13a senses the temperature in the refrigerating chamber as a heat-sensitive tube, and expands and contracts the heat-sensitive operation, that is, the bellows 13b, and the expansion-contraction force is applied. 13c is a moving plate, which balances the pressure of the bellows 13c with the force of the elastic body engaged with the operating plate 13c, that is, the force of the spring 13e, and the point 13c '. Is a damper, and the operating plate 13c is rotated at the shaft portion l3d '. Are transitively connected. The damper 13d is opened and closed by the rotational movement of the operating plate 13c. However, the damper 13d is attached inclined (A dimension &gt; B dimension) in the open state, and the upper end portion is a hole 14a between the ducts. The hole 14a between the ducts is opened and closed while rotating the upper end portion to the point at the position where it is in contact with the.

Next, since the damper thermostat main body part is the same as the conventional example, description is abbreviate | omitted and the structure and opening / closing operation | movement of a damper part are demonstrated in more detail.

The damper 13d is supported by the front end of the operation plate 13c freely via the support member 13d-1. The support member 13d-1 is a rear portion of the damper and is provided slightly above the center position G of the damper 13d. Moreover, the length of the support member 13d-1 is 1. 13d 'is a part which rotationally supports the front-end | tip of the operation plate 13c and the support member 13d-1 as an axial part.

That is, the damper 13d is operated so that the lower part of the damper is always in contact with the operation plate 13c by its own weight because the connection portion with the operation plate 13c is above the center. Therefore, in a state where the damper does not contact the hole 14a between the ducts, the lower part of the damper is always opened wider than the upper part. On the other hand, in the closed state, the damper is pushed into the hole 14a between the ducts against the weight of the damper so that the hole 14a between the ducts is closed.

When the damper 13d is in the closed state in the open state, first, the rotational motion of the operating plate 13c is transmitted to the damper 13d, and the upper end of the damper 13d is connected to the hole 14a between the ducts. In addition, when the operation plate 13c operates, the damper closes the lower end with the upper end of the hole 14a between the ducts as an axis, and both of them are in a closed state. When opened next, it falls from the lower end of the hole 14a between the ducts by the weight of the damper and then falls off the upper end. Since the lower end of the damper 13d is brought into contact with the operation plate 17 in the completely separated state, the distance A from the lower portion of the hole 14a between the ducts to the damper 13d and between the duct and the hole 14a. The relationship of the distance B from the upper part to the damper 13d becomes A> B.

As described above, the opening and closing operation of the hole 14a between the ducts is determined by the rotational movement force of the operation plate 13c that moves the damper 13d, and optimally maintains the amount of cold air supplied to maintain a constant temperature in the refrigerating chamber. Cold air that has been supplied and dropped from the freezer compartment to the refrigerating compartment is guided downward by the inclination of the damper 13d. Therefore, since cold air does not directly contact the heat insulating material 15 of the upper part of the damper, since there is no intrusion of cold air into the gap between the heat insulating material 15 and the refrigerating chamber ceiling part 6b, frost can be prevented from occurring reliably. In addition, the cool air is discharged into the refrigerating chamber and the meat case 16 by a passage formed in the heat insulating material 15. Moreover, the heat insulating material 15 is provided so that it may contact the refrigerator compartment ceiling part 7b. In addition, the cold air discharge to the meat case 16 is a meat case (not shown) through a passage formed in the heat insulating material 15 by changing the wind direction upward of a portion of the cold air once guided downward through the holes 14a between the ducts. To the outlet).

Since the meat case has a very small volume compared to the volume in the refrigerator compartment, it is only necessary to distribute a part of the cold air discharged to the refrigerator compartment.

The distribution of the meat case cold air has little effect on the cooling capacity of the refrigerator compartment. Further, when the main body structure of the damper thermostat is shown in FIGS. 6 to 9, the reliability of the damper thermostat is further improved.

That is, a part of both sides of the horizontal edge part 13c-1 of the operation plate 13c is excavated in L shape. 13c-2 is a groove portion having an approximately L shape as described above. This groove portion 13c-2 has an angle θ ₂ as shown in FIG. 9. 13c-3 is a bearing portion having a bearing hole 13c-4. A shaft portion 13-1 formed by bending a part of the damper thermostat main body 13 is connected to the bearing 13c-3. The shaft portion 13-1 has a plate shape, and a plate-shaped piece abuts against the bent portion of the bearing portion 13c-3. Reference numeral 13-2 is a small protrusion provided at the tip of the shaft portion 13-1 and inserted into the bearing hole 13c-4.

The L-shaped groove 13c-2 of the operating plate 13c has a bend angle θ ₂ , and is bent so as to be θ ₂ <90 ° with respect to the tensile angle θ ₁ of the spring 13e. Therefore, in the position where the operating plate 13c is closed (the damper is closed), as shown in FIG. 9, the bearing portion serving as the groove part 13c-2 of the operating plate 13c with respect to the spring tension F ( 13c-3 acts on the component force f ₁ direction (upward direction), so that the shaft portion 13-1 is always pushed to the bottom portion of the bearing portion 13c-3 to be a fixed point position.

Therefore, since there is no shift of the operation plate 13c, there is no shift of the damper, the opening / closing operation of the hole between the ducts becomes stable, and a reliable damper thermostat for a refrigerator can be obtained.

As described above, the damper provided in the refrigerating chamber cold air inlet is inclined (A dimension &gt; B dimension), so that the real material is not necessary in the gap between the refrigerating chamber ceiling and the insulator, and the heat insulating material can be designed thinly. It is also excellent in terms of saving money. In addition, since cold air is induced by the principle of natural fall, it is effective in terms of saving electric power due to less pressure loss in the damper portion and less amount of energy supplied to the refrigerator compartment.

In addition, if grooves are provided at both edges of the operation plate, and the one side of the groove is bent to engage the bearing portion of the case body, the bent portion of the operation plate can be easily processed, and the angle of the bent portion can be obtained freely. Also, regardless of the internal pressure of the bellows (with respect to the internal pressure drop of the bellows due to the temperature condition), it is always possible to set a certain position as a point, so there is an advantage that there is no change in the operating value.

Claims (2)

An operation in which the open hole 14a of the duct 14 for supplying the cold air of the freezing chamber 5 to the refrigerating chamber 6 is controlled by the damper thermostat main body 13 having the elastic body 13e and the thermal reactant 13b. In the damper thermostat for a refrigerator which controls the supply amount of cold air by opening / closing with the damper 13d attached to the plate 13c, the damper 13d is attached to the operating plate 13c at a position above the center point. The damper thermostat for a refrigerator characterized in that the damper is inclined downward to open the open hole portion (14a) to be attached downward. The method according to claim 1, wherein L-shaped grooves 13c-2 are provided at both sides of the operation plate 13c, and the bend angle θ ₂ of the grooves is tensioned of the elastic body 13e. Damper thermostat for refrigerator, perpendicular to the angle (θ ₁ ).

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